KR102280025B1 - Signal transmission module and camera apparatus - Google Patents

Abstract

The present invention relates to a camera device. The camera device includes: a housing; a camera module located in the housing, having a lens unit moving in an optical axis direction and an image sensor unit coupled to the lens unit, and providing position alignment by moving in a direction crossing the optical axis direction; and a signal transmission module positioned in the housing and connected to the image sensor unit to transmit an image signal output from the image sensor unit. The signal transmission module includes a signal transmission unit having a bending portion whose extension direction is changed to the opposite direction, and a first buffering unit positioned between the signal transmission unit and the inner surface of the housing adjacent to the signal transmission unit. According to the present invention, damage or breakage of the signal transmission unit due to the positioning of the camera device is prevented.

Description

Signal transmission module and camera device {SIGNAL TRANSMISSION MODULE AND CAMERA APPARATUS}

The present invention relates to a signal transmission module and a camera device.

Nowadays, a camera device mounted on an electronic device such as a mobile phone takes an image using the same image sensor of an imaging device (charge coupled device (CCD)).

Accordingly, recent camera devices include a lens unit to which a lens is mounted, an image sensor unit positioned on the lens and having an image sensor, and an image signal processing module for processing an image signal applied from the image sensor unit.

Such a camera device is provided with an anti-shake device and a position aligning device for adjusting the position of the lens unit to align the position or focus of the lens unit in order to prevent bad shooting due to external shock or hand shake during photographing.

Accordingly, a correction operation is performed to correct the positional deviation of the lens unit due to external impact, etc., and accurate alignment of the lens unit is performed.

In this case, the lens unit aligns the position of the lens unit by adjusting the position of the lens unit not only in the optical axis direction (ie, the lens mounting direction) but also in the direction intersecting the optical axis direction.

However, according to the alignment operation of the lens unit, the position of the signal transmission unit made of a flexible substrate that transmits the image signal output from the image sensor to the image signal processing module is also distorted according to the alignment of the lens unit.

Accordingly, there is a problem in that the signal transmission unit is damaged due to the distortion of the signal transmission unit due to the frequent positioning operation. Also, the connector part is located at both ends of the signal transmission unit for connection with other devices such as an image sensor. Damage to the connector may also occur.

Republic of Korea Patent Publication No. 10-2006-0081889 (published date: July 14, 2006, title of invention: horizontal correction device for camera lens unit) Korean Patent Laid-Open Publication No. 10-2012-0066294 (published date: June 22, 2012, title of invention: vehicle camera device)

A camera device according to one aspect of the present invention includes a housing, a lens unit moving in the optical axis direction, and an image sensor unit coupled to the lens unit, located in the housing, and moving in a direction crossing the optical axis direction to achieve position alignment and a signal transmission module positioned within the housing and connected to the image sensor unit to transmit an image signal output from the image sensor unit. In this case, the signal transmission module includes a signal transmission unit having a bending portion whose extension direction is changed to the opposite direction, and a first buffering unit located between the signal transmission unit and the inner surface of the housing adjacent to the signal transmission unit.

The first cushioning portion contains a cushioning material and has a plate shape and can be attached to the inner surface of the adjacent housing.

The first cushioning unit may include a body containing a cushioning material and having a plate shape, which is attached to the inner surface of the adjacent housing, and at least one protrusion protruding from the body toward the adjacent signal transmitting unit.

The first buffering part may be an elastic member positioned on the inner surface of the adjacent housing and protruding toward the adjacent signal transmitting part.

The elastic member may be attached to the inner surface of the housing.

The elastic member may extend seamlessly to the housing and protrude toward the adjacent signal transmission unit.

The signal transfer module may further include a second buffer that is positioned between the signal transfer units facing each other in opposite directions to space the adjacent signal transfer units.

The second buffer portion is located adjacent to the bending portion, one side of the second buffer portion may be surrounded by the bending portion and the other side may be opened.

The first buffer unit may be positioned adjacent to the second buffer unit.

The second buffer unit may include a pair of buffer members respectively positioned on inner surfaces of the two adjacent signal transmission units.

A signal transmission module according to another aspect of the present invention is located between a signal transmission unit having a bending portion whose extension direction is changed to the opposite direction, and a housing adjacent to the signal transmission unit and the signal transmission unit and surrounding the signal transmission unit. It includes a first buffer that does.

The signal transfer module according to the above feature may further include a second buffer that is positioned between the signal transfer units facing each other in opposite directions to space the adjacent signal transfer units.

The second buffer portion is located adjacent to the bending portion, one side of the second buffer portion may be surrounded by the bending portion and the other side may be opened.

The first buffer unit may be positioned adjacent to the second buffer unit.

According to a feature of the present invention, even if the position of the camera device is aligned, even if a distortion phenomenon of the signal transmission unit or movement in the vertical direction occurs, the force transmitted to the signal transmission unit by the buffer unit located in the signal transmission unit is relieved and distributed. .

Accordingly, damage or breakage of the signal transmission unit due to alignment of the camera device is prevented.

1 is a perspective view of a camera device according to an embodiment of the present invention, illustrating a state in which a first case of a housing is separated.
FIG. 2 is a bottom view of the camera device shown in FIG. 1 .
FIG. 3 is an exploded perspective view of the camera device shown in FIG. 1 .
FIG. 4 is an enlarged view of a part of a signal transmission module of the camera device shown in FIG. 1 .
5 and 6 are diagrams illustrating various examples of the first buffer unit of the signal transmission module in the camera device according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that adding a detailed description of a technique or configuration already known in the relevant field may make the gist of the present invention unclear, some of these will be omitted from the detailed description. In addition, the terms used in this specification are terms used to properly express the embodiments of the present invention, which may vary according to a person or custom in the relevant field. Accordingly, definitions of these terms should be made based on the content throughout this specification.

The terminology used herein is for the purpose of referring to specific embodiments only, and is not intended to limit the invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite. As used herein, the meaning of 'comprising' specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component, and/or group. It does not exclude the existence or addition of

Hereinafter, a signal transmission module and a camera device having the same according to an embodiment of the present invention will be described with reference to the accompanying FIGS. 1 to 6 .

1 and 2 , the camera device according to an embodiment of the present invention includes a housing 10 , a lens unit 20 coupled to the housing 10 , and a lens unit 20 positioned below the lens unit ( An image sensor unit 30 coupled to the 20 , and a signal transmission module 40 connected to the image sensor unit 30 may be provided.

The housing 10 may include a first case 11 , a second case 12 , and a second case 13 as shown in FIG. 2 .

In this case, the first case 11 may have a side surface 111 and an upper surface 112 , and a lower portion of the first case 11 may be opened. Accordingly, the first case 11 may be a case that mainly surrounds a part of the side surface and the upper surface of the camera device.

The first case 11 has a lens protrusion H11 through which a part of the lens unit 20 protrudes, and a part of the lens unit 20 mounted inside the first case 11 forms the lens protrusion H11. can be exposed to the outside.

The rear end of the side surface 111, that is, a portion corresponding to the signal transfer module 40 is open, so that a part of the signal transfer module 40 located inside the first case 11 is exposed to the outside through the open rear end. are exposed

The second case 12 is coupled to the lower surface of the image sensor unit 30 positioned in the inner space of the first case 11 to protect the image sensor unit 30 from the outside.

The third case 13 surrounds a portion of a lower surface and a rear end of the first case 11 coupled to the first case 11 and opened.

Accordingly, the third case 13 has a lower surface 131 , a rear surface 132 , and a right surface 133 as shown in FIG. 3 , and the left and upper portions are open.

The rear surface 132 is inserted into the interior of the first case 11 , and the right side 133 is coupled to the rear end of the opened first case 11 .

At this time, the upper end of the right side surface 133 has a stepped structure in which the middle part is concave, and by this step structure, between the inner surface of the upper surface 12 of the first case 11 and the upper end of the right side surface 133 . A gap occurs in the

Accordingly, as shown in FIG. 2 , a part of the signal transmission module 40 is exposed to the outside through this gap.

Accordingly, the first case 11 forms a part of the side surface and the upper surface of the housing 10 , the second case 12 forms a part of the lower surface of the housing 10 , and the third case 13 forms a part of the housing 10 . part of the back and part of the side.

In the inner space of the housing 10 formed by being surrounded by the first to third cases 11-13, the lens unit 20, the image sensor unit 30, and the signal transmission module 40 are provided, as already described. Located.

The lens unit 20 is located in the housing 10 and moves in the optical axis direction.

The lens unit 20 includes a lens assembly 21 having at least one lens and a lens driving unit 22 coupled to the lens assembly 21 to adjust the focus of the lens assembly 21 . If necessary, a lens housing 23 accommodating the lens assembly 21 and the lens driving unit 23 may be further provided.

Accordingly, the lens assembly 21 may move in the optical axis direction (eg, the vertical direction in FIG. 3 ) Y1 along the optical axis by the operation of the lens driving unit 22 to perform focus adjustment.

In addition, by controlling the tilting state of the lens assembly 21 and the housing 10 , alignment of the lens assembly 21 and the housing 10 in a horizontal direction (eg, a planar direction) may be performed. .

To this end, as shown in FIG. 1 as an example, the camera device of this example is positioned on the lens protrusion H11 of the housing 10 to align the lens unit 20 or the housing 10 in the horizontal direction. It may further include a position aligning unit (50).

The alignment unit 50 is coupled to the lens unit 20 to align the lens unit 20 in a first direction (eg, the first horizontal direction in FIG. 3 ) X1 of a pair of first alignment A pair of second alignment pins 52 coupled to the pin 51 and the housing 10 to align the housing 10 in the second direction (eg, the second horizontal direction in FIG. 3 ) (X2) can be provided.

The first horizontal direction X1 and the second horizontal direction X2 are both directions crossing the optical axis direction Y1 , and the first horizontal direction X1 and the second horizontal direction X2 may be orthogonal to each other.

A pair of first alignment pins 51 facing each other in opposite directions are coupled to corresponding portions of adjacent lens units 20, respectively, and a pair of second alignment pins facing each other in opposite directions are also opposite to each other. The alignment pins 52 are each engaged with a corresponding portion of the adjacent housing 10 .

Therefore, by the driving device of the alignment unit 50 (not shown), the alignment unit 50 moves in the left and right directions around the first direction (X1) or the second direction (X2), that is, by tilting it. In addition to the lens unit 20 itself, the planar position of the housing 10 to which the lens unit 20 is coupled may be aligned.

By the tilting operation of the positioning unit 50 , the lens unit 20 and the housing 10 are aligned, so that an assembly error occurring during the assembly process of the camera device is corrected.

The alignment of the positions of the lens unit 20 and the housing 10 is already known, so a detailed description thereof will be omitted herein. In addition, it goes without saying that all structures for aligning the position of the camera device using other methods as well as the illustrated example are applied to the camera device of the present invention.

The image sensor unit 30 having an image sensor such as an imaging device (CCD) is coupled to the lens unit 20 and generates an image signal using light incident through the lens unit 20 .

The image sensor unit 30 is connected to the signal transmission module 40 as shown in FIGS. 1 and 3 and outputs the image signal generated through the signal transmission module 40 to an image signal processing module (not shown). will do

The lens unit 20 of the present example and the image sensor unit 30 coupled to the lens unit 20 may constitute a camera module of the camera device according to the present example. Accordingly, the camera module is located in the housing 10 and includes a lens unit 20 moving in the optical axis direction and an image sensor unit 30 coupled to the lens unit 20, and moving in a direction crossing the optical axis direction. Position alignment is done.

The signal transmission module 40, as shown in FIGS. 2 and 4, is a signal having at least one bending portion 411 that is bent at least once by changing the direction of extension to the opposite direction, that is, bending. The transmission unit 41, the buffer unit 42 located between the signal transmission unit 41 facing each other in opposite directions, at least one buffer unit located between the signal transmission unit 41 and the housing 10 ( 43) and a connector portion 44 for connection with other devices.

The connector unit 44 is positioned at both ends of the signal transmission unit 41 to perform electrical and physical connection with a corresponding device (eg, the image sensor unit 30 and the image signal processing module).

The signal transmission unit 41 has a flexible property, and as shown in FIG. 4 , it extends in the first extension direction D1 and then bends to the opposite of the first extension direction "?戮* second extension direction D2" can be extended to

Accordingly, the signal transfer unit 41 alternately extends in the first extension direction D1 and the second extension direction D2 without interruption, and as shown in FIG. 4 , the side surface of the signal transfer unit 41 has a plurality of sides. It has a structure in which the layers are stacked spaced apart along the vertical direction in a meandering form.

The signal transmission unit 41 may be formed of a flexible printed circuit board (FPCB, flexible printed circuit board (PCB)).

Although the drawing does not show signal lines or electrical and electronic devices located in the signal transmission unit 41 for convenience of illustration, in reality, the signal transmission unit 41 includes signal lines for input/output of signals or power supply and the operation of the camera device. Electrical and electronic devices for the purpose may be printed and mounted.

As described above, since the signal transmitting unit 41 of the signal transmitting module 40 has a structure that is bent to have at least one bending portion 411 to perform electrical and physical connection between the two devices, the position of the camera device Damage or breakage of the signal transmission unit 41 due to alignment is greatly reduced or reduced.

That is, when the tilting operation is performed to align the position of the camera device, the signal transmission module 40 also tilts in the corresponding direction by the tilting operation of the lens unit 20 to which the image sensor unit 30 is coupled. .

At this time, when the signal transmission unit is formed in a straight line extending in only one direction in a limited space in which the signal transmission module 40 is located, the torsional strength due to the tilting of the image sensor unit 30 is the signal transmission unit ( 41) is transmitted as a whole. Therefore, due to the distortion of the signal line or the electrical and electronic device located in the signal transmission unit 41, it adversely affects the connection state or the mounting state, and also damage or breakage of the connector unit 44 of the signal transmission module 40 occurs. . Due to this, the normal signal transmission is not performed, and thus a malfunction of the camera device occurs.

However, as in this example, when the signal transfer module 40 has a structure in which a plurality of layers are stacked by bending the signal transfer unit in a limited space in which the signal transfer module 40 is located, the length of the signal transfer unit 41 simply extends in one direction. will be much higher than it would have been. Accordingly, the torsional strength transmitted to the signal transmitting unit 41 due to the tilting of the image sensor unit 30 decreases in proportion to the increased length of the signal transmitting unit 41 . Accordingly, damage or breakage of the signal transmission unit 41 and signal lines or electrical and electronic devices positioned thereon is prevented or reduced.

In addition, since the twist strength applied to the connector part 41 of the signal transmission module 40 is also greatly weakened due to the increased length of the signal transmission unit 411 , compared to the case where the signal transmission unit is extended in only one direction, the corresponding device The degree of distortion and the strength of the connector part 41 for physical connection with the connector part 41 are also greatly reduced, so that damage to the connector part 41 is prevented or greatly reduced.

As described above, the signal transmission module 40 having the bending portion 411 due to at least one bending operation includes two types of cleavage portions 42 and 43 . Hereinafter, the buffer unit 43 in which the housing 10 is located between the signal transmission units 41 is referred to as a 'first buffer unit', and the buffer unit 42 located between two adjacent signal transmission units 41 . is called a 'second buffer unit'.

Among these two buffers (42, 43) will be described first from the second buffer (42).

The second buffer unit 42 may be positioned between the signal transfer units 41 facing each other in opposite directions to space the adjacent signal transfer units 41 apart.

This second buffer portion 42 may be located adjacent to the bending portion 411, but is limited thereto. Therefore, when the second buffer part 42 is located adjacent to the bending part 411, one side of the second buffer part 42 is surrounded by the bending part 411, and the other side facing the one side is to be opened. can

The second buffering part 42 is a pair of buffering members 421 and 422 respectively located on the inner surface of the signal transmitting part 41 located in layers adjacent to each other facing each other in opposite directions (eg, in the vertical direction). ) is provided.

At this time, the pair of cushioning members 421 and 422 have the same structure except that only the positioned portions (the inner lower surface and the inner upper surface of the bending portion 411) are different.

The buffer members 421 and 422 of the present example may include an elastic material such as silicone or a sponge, or may have an elastic structure.

As an example, the buffer members 421 and 422 may have a plate shape, such as a hexahedral structure, such as a cuboid having an elastic material.

Accordingly, the signal transfer unit 41 facing each other on the opposite side in the bending portion 411 is spaced apart from each other by more than the total thickness of the two cushioning members 421 and 422 forming a pair.

For this reason, even if the position or bending shape of the signal transmission unit 41 is changed due to the twisting phenomenon of the signal transmission module 40, the spacing between the bending portions 411 by the pair of buffer members 421 and 422 is constant. Keep more than spacing. Accordingly, a problem in which the signal transfer unit 41 is damaged or damaged in the bending portion 411 is prevented.

In addition, even if the signal transmission unit 41 fluctuates due to torsion or shaking of the signal transmission module 40 in the vertical direction, by the buffer members 421 and 422 that are located in opposite directions and collide with each other, the signal transmission unit ( 41), the applied force is absorbed and dispersed. Accordingly, the impact applied to the signal transmission unit 41 is reduced to protect not only the signal transmission unit 41 but also the signal lines and electrical and electronic devices positioned in the signal transmission unit 41 .

In addition, the signal transmission module 40 is further protected from external force by the at least one first buffering unit 43 .

That is, each of the first buffering units 43 is located between the signal transmitting unit 41 and the signal transmitting unit 41 and a portion of the housing 10 adjacent to the signal transmitting unit 41 due to shaking of the signal transmitting unit (41). 41) is protected.

In this example, the first buffer 43 is between the signal transmission unit 41 and the inner surface of the upper surface 112 of the first case 11 of the housing 10 and the signal transmission unit 41 and the housing 10 . It may be located between the inner surface of the lower surface 131 of the third case 13 of the

At this time, the position of the signal transfer unit 41 in which each first buffer unit 43 is located may be adjacent to the bending portion 411 in which the pair of second buffer units 42 are located.

Accordingly, as shown in FIG. 4 , when two bending parts 411 are present in the signal transmission unit 41 , two first buffer units 43 are present.

Accordingly, one first buffer part 43 is located on the lower surface 131 of the third case 13 of the housing 10 or the corresponding part (eg, the bending part 411) of the signal transmitting part 41 lower surface It may be positioned between the bending portion 411 and the lower surface 131 of the third case 13 of the housing 10 .

In addition, the remaining first buffering unit 43 is located on the corresponding portion of the signal transmitting unit 41, for example, on the remaining bending portion 411 or on the inner surface of the upper surface 112 of the first case 11, the corresponding bending It may be positioned between the portion 411 and the upper surface 112 of the first case 11 of the housing 10 .

The plurality of first buffering parts 43 all have the same structure, and absorb the impact applied to the outside by providing an elastic material or an elastic structure.

An example of the structure of such a first buffer part 43 is shown in FIGS. 5 and 6 .

First, as shown in Figure 5 (a), the first buffer portion 43 is a body 431 made of a buffer material and at least one protrusion 432 protruding upward from the upper surface of the body 431 . can be provided.

Both the body 431 and the protrusion 432 may include an elastic material.

The body 431 may have a plate shape such as a hexahedron, such as a rectangular parallelepiped, and the protrusion 432 may protrude from the upper surface of the body 431 toward the adjacent signal transmission unit 411 .

In Figure 5 (a), the projection 432 is made of a plurality of spaced apart along the extending direction of the body 431, but is not limited thereto and may be formed of one.

The first buffering part 43 is positioned so that the protrusion 432 is adjacent to or in contact with the adjacent signal transmission part 41 .

Accordingly, as shown in FIG. 4 , the lower surface of the body 431 of the first buffer part 43 positioned on the bending part 411 positioned adjacent to the third case 13 is the third case 13 . The lower surface of the body 431 is located in contact with the lower surface 131 and the first buffer part 43 positioned in the bending portion 411 positioned adjacent to the first case 11 has a lower surface of the first case 11 . It may be positioned in contact with the inner surface of the upper surface 112 .

At this time, the lower surface of the body 431 of the first buffer unit 43 is applied to the corresponding surface (that is, the lower surface 131 of the third case 13 or the upper surface 112 of the first case 11). It can be attached using

The protrusion 432 of the first buffering unit 43 may be in contact with the corresponding portion of the signal transmitting unit 41 or may be spaced apart adjacently.

However, the present invention is not limited thereto, and in an alternative example, the first buffer part 43 may include only the body 411 or a plurality of protrusions 432 arranged to be spaced apart in the corresponding direction.

As another example, as shown in Figure 5 (b), the first buffer 43 is made of an elastic member such as a spring (spring), such as a plate spring (plate spring) or coil spring (coil spring), the corresponding It may be attached to the surfaces 112 and 131 . As such, when the first buffering part 43 is made of an elastic member, the first buffering part 43 is located on the inner surface of the adjacent housing 10 and protrudes toward the adjacent signal transmission part.

After the second armband 43 as shown in FIG. 5 is manufactured as a separate component, it may be separately attached to the mounting portion by using an adhesive or soldering process. Accordingly, the first buffer 43 may be made of a component separate from the components 11 and 13 to which they are attached.

However, the first buffer part 43 of this example can be manufactured integrally with the parts 11 and 13 by seamlessly connecting the parts 11 and 13 to be mounted thereon.

In this case, the first buffering part 43 may be formed of a protrusion that protrudes from the corresponding cases 11 and 13 toward the corresponding direction and has an elastic force.

To this end, as shown in FIG. 6 , the first buffering part 43 may be a protrusion formed by cutting the case portion located at the corresponding position of the case 11 and 13 and then bending it in the corresponding direction. In this case, the openings H43 are generated in the cases 11 and 13 by the cutting operation. Therefore, the opening H43 generated by the formation of the first buffer part 43 is covered with a separate insulating film or insulating plate, etc. to prevent the inflow of foreign substances such as dust or moisture into the signal transmission module 50 . there is.

However, the first buffer 43 may be a protrusion that is integrally manufactured with the corresponding cases 11 and 13 and protrudes from the corresponding position in the corresponding direction. In this case, a separate opening due to the formation of the first buffer part 43 does not occur in the corresponding cases 11 and 13 .

As such, the signal transmission module 40 of this example further includes a first buffer unit 43 positioned between the signal transmission unit 41 and the corresponding cases 11 and 13 in addition to the second buffer unit 42 .

Accordingly, when the position of the lens unit 20 and the housing 10 are aligned by the first buffer unit 43 , the position of the image sensor unit 30 coupled to the lens unit 20 is changed, resulting in a signal Even if the signal transmission unit 41 of the transmission module 40 shakes or twists in the vertical or horizontal direction, a phenomenon in which the signal transmission unit 41 directly collides with the adjacent housing 10 is prevented.

The bending part 411, which is heavier than other parts due to the mounting of the second buffer part 42, has a higher degree of shaking or distortion than other parts due to the weight, so the probability of colliding with the adjacent housing 10 is high, and the housing 10 ), the impact applied to the bending portion 411 and the housing 10 when colliding with it is much greater than that of other parts.

However, when the first buffering part 43 is positioned between the bending part 411 on which the second buffering part 42 is mounted and the corresponding housing 10 part, the bending part 41 is attached to the housing 10 . Instead of colliding directly with the second cushion layer 43, the impact applied to the housing 10 and the bending section 41 is greatly alleviated.

In particular, as shown in Fig. 5 (a), when the first buffer part 43 is provided with a plurality of projections 432 that protrude from the body 411 and are spaced apart from each other, it is transferred to the first buffer part 43 The impact is improved due to the protrusions 422 spaced apart from each other. Accordingly, the size of the impact transmitted to the corresponding housing 10 portion is further reduced.

In the above, embodiments of the signal transmission module and the camera device of the present invention have been described. The present invention is not limited to the above-described embodiments and the accompanying drawings, and various modifications and variations will be possible from the point of view of those of ordinary skill in the art to which the present invention pertains. Accordingly, the scope of the present invention should be defined not only by the claims of the present specification, but also by those claims and their equivalents.

10: housing 20: lens unit
30: image sensor unit 40: signal transmission module
41: signal transmission unit 411: bending part
42: second buffer portion 421, 422: buffer member
43: first buffer unit

Claims (14)

housing;
a camera module located in the housing, having a lens unit moving in an optical axis direction and an image sensor unit coupled to the lens unit, and configured to move in a direction crossing the optical axis direction; and
A signal transmission module located in the housing and connected to the image sensor unit to transmit an image signal output from the image sensor unit
including,
The signal transmission module,
a signal transmission unit having a bending portion whose extension direction is changed to the opposite direction;
a first buffer positioned between the bending part of the signal transmission part and the inner surface of the housing adjacent to the bending part; and a pair of cushioning members respectively positioned on the first and second portions of the signal transmission unit facing in opposite directions with respect to the bending portion to maintain a constant spacing between the first portion and the second portion. 2nd buffer to keep
including,
The first buffer and the second buffer are facing each other from opposite sides of the camera device. In claim 1,
The first buffer portion contains a buffer material and has a plate shape and is attached to the inner surface of the adjacent housing. In claim 1,
The first buffer unit,
a body containing a cushioning material and having a plate shape attached to the inner surface of the adjacent housing; and
at least one protrusion protruding from the body toward an adjacent signal transmission unit
A camera device comprising a. In claim 1,
The first buffer unit is an elastic member positioned on the inner surface of the adjacent housing and protruding toward the adjacent signal transmitting unit. In claim 4,
and the elastic member is attached to the inner surface of the housing. In claim 4,
The elastic member extends seamlessly to the housing and protrudes toward the adjacent signal transmission unit. delete In claim 1,
The second buffer is positioned adjacent to the bending portion, and one side of the second buffer is surrounded by the bending portion and the other side is open. delete delete a signal transmission unit having a bending portion whose extension direction is changed to the opposite direction;
a first buffer positioned between the bending portion of the signal transmission unit and the housing adjacent to the bending portion and enclosing the signal transmission unit; and
A pair of cushioning members respectively positioned in the first and second portions of the signal transmission unit facing in opposite directions with respect to the bending portion are provided to uniformly maintain a spacing between the first portion and the second portion 2nd buffer to hold
including,
The first buffer unit and the second buffer unit are opposite to each other to face each other signal transmission module. delete In claim 11,
The second buffer part is located adjacent to the bending part, and one side of the second buffer part is surrounded by the bending part and the other side is open. delete

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